WO2022048288A1 - Geological feature constraint-based reservoir parameter prediction method, apparatus, and storage medium - Google Patents

Geological feature constraint-based reservoir parameter prediction method, apparatus, and storage medium Download PDF

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WO2022048288A1
WO2022048288A1 PCT/CN2021/103487 CN2021103487W WO2022048288A1 WO 2022048288 A1 WO2022048288 A1 WO 2022048288A1 CN 2021103487 W CN2021103487 W CN 2021103487W WO 2022048288 A1 WO2022048288 A1 WO 2022048288A1
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neural network
seismic
deep neural
network model
data
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PCT/CN2021/103487
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French (fr)
Chinese (zh)
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许凯
孙振涛
王世星
唐金良
曹慧兰
张如一
郑笑雪
姚铭
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中国石油化工股份有限公司
中国石油化工股份有限公司石油物探技术研究院
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Priority claimed from CN202010931370.2A external-priority patent/CN114152978B/en
Priority claimed from CN202010928912.0A external-priority patent/CN114152977B/en
Application filed by 中国石油化工股份有限公司, 中国石油化工股份有限公司石油物探技术研究院 filed Critical 中国石油化工股份有限公司
Priority to US18/005,011 priority Critical patent/US20230314649A1/en
Publication of WO2022048288A1 publication Critical patent/WO2022048288A1/en

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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V1/00Seismology; Seismic or acoustic prospecting or detecting
    • G01V1/40Seismology; Seismic or acoustic prospecting or detecting specially adapted for well-logging
    • G01V1/44Seismology; Seismic or acoustic prospecting or detecting specially adapted for well-logging using generators and receivers in the same well
    • G01V1/48Processing data
    • G01V1/50Analysing data
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V1/00Seismology; Seismic or acoustic prospecting or detecting
    • G01V1/28Processing seismic data, e.g. for interpretation or for event detection
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V1/00Seismology; Seismic or acoustic prospecting or detecting
    • G01V1/28Processing seismic data, e.g. for interpretation or for event detection
    • G01V1/30Analysis
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06NCOMPUTING ARRANGEMENTS BASED ON SPECIFIC COMPUTATIONAL MODELS
    • G06N3/00Computing arrangements based on biological models
    • G06N3/02Neural networks
    • G06N3/04Architecture, e.g. interconnection topology
    • G06N3/044Recurrent networks, e.g. Hopfield networks
    • G06N3/0442Recurrent networks, e.g. Hopfield networks characterised by memory or gating, e.g. long short-term memory [LSTM] or gated recurrent units [GRU]
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06NCOMPUTING ARRANGEMENTS BASED ON SPECIFIC COMPUTATIONAL MODELS
    • G06N3/00Computing arrangements based on biological models
    • G06N3/02Neural networks
    • G06N3/04Architecture, e.g. interconnection topology
    • G06N3/045Combinations of networks
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06NCOMPUTING ARRANGEMENTS BASED ON SPECIFIC COMPUTATIONAL MODELS
    • G06N3/00Computing arrangements based on biological models
    • G06N3/02Neural networks
    • G06N3/08Learning methods
    • G06N3/088Non-supervised learning, e.g. competitive learning

Definitions

  • the present disclosure belongs to the technical field of geophysical exploration, and in particular, relates to a method, device, computer storage medium and computer equipment for predicting reservoir parameters based on geological feature constraints.
  • this technology mainly uses depth domain "wavelet” extraction, combined with conventional inversion technology, to carry out direct prediction of elastic parameters, but the theoretical model based on depth domain data has not been established, so the basic theory is insufficient; the third is represented by Jason company
  • the depth-domain reservoir parameter prediction method based on high-precision velocity volume transformation, this method converts the depth-domain data into time-domain data for conventional reservoir parameter prediction, but the deep-time transformation has a certain transformation cumulative error, and it is time-consuming and labor-intensive. It is not conducive to improving the reservoir prediction accuracy.
  • the present disclosure proposes a method, device, computer storage medium, and computer equipment for predicting reservoir parameters based on geological feature constraints.
  • the present disclosure provides a method for predicting reservoir parameters based on geological feature constraints, comprising the following steps:
  • step S100 includes the following steps:
  • the correlation between different types of seismic attributes of the target interval and the reservoir parameters is determined through intersection analysis, and the correlation degree is selected from different types of seismic attributes that exceed the preset correlation.
  • the seismic attribute of the degree threshold is regarded as the dominant seismic attribute;
  • the data of the seismic attribute is decomposed and reconstructed by singular spectrum analysis, wherein in the reconstructed sequence, the contribution degree is kept higher than the preset contribution according to the contribution degree of the seismic attribute
  • the sequence component of the degree threshold is used as the dominant component of the dominant seismic attribute.
  • the waveform classification network model is an SOM unsupervised network model designed based on the SOM unsupervised clustering algorithm, and the network model includes a seismic attribute input layer and a classification result output layer.
  • the geological features comprise sedimentary features.
  • each of the deep neural network models is an LSTM-RNN recurrent neural network model, and the network model includes a seismic attribute input layer, a reservoir parameter output layer, and a seismic attribute input layer. and the hidden layer between the reservoir parameter output layer; wherein, the hidden layer includes:
  • the dropout layer is used to alleviate the overfitting phenomenon in the network model training process
  • regression layer which is used as the output for training the network model.
  • the step S400 further includes:
  • Different deep neural network models are trained using seismic data and logging data belonging to the target interval to optimize the model parameters of each deep neural network model.
  • the spatial variation coefficient of each trained deep neural network model in the spatial variation neural network prediction model set is determined based on the similarity of the waveforms and the spatial distance.
  • step S600 different trained deep neural network models are fused into a set of spatially varying neural network prediction models according to the following formula:
  • V p represents the reservoir parameters
  • f k (x 1 , x 2 ,...x N ) represents the deep neural network model under the kth geological feature
  • wk , i, j represent the kth geological feature under the
  • the spatial variation coefficients of the deep neural network model, x 1 , x 2 , ... x N represent different types of seismic attributes.
  • w is the spatial variation coefficient
  • v 1 is the seismic trace of the deep neural network model that has been constructed
  • v 2 is the seismic trace of the deep neural network model to be constructed
  • w c represents the seismic trace of the deep neural network model that has been constructed and the depth to be constructed.
  • the interpolation coefficient of the waveform similarity of the neural network model seismic trace w d represents the interpolation coefficient of the distance between the seismic trace of the built deep neural network model and the seismic trace of the deep neural network model to be constructed
  • c 12 represents the correlation between v 1 and v 2
  • d 12 represents the distance between v 1 and v 2
  • is the adjustment factor
  • ⁇ c and ⁇ d are the exponential factors.
  • the above-mentioned reservoir parameters of the target interval include a spatial three-dimensional elastic parameter volume of the target interval
  • the method further includes outputting a distribution map of the spatial three-dimensional elastic parameter volume of the target interval.
  • the present disclosure also provides a reservoir parameter prediction device based on geological feature constraints, characterized in that it includes:
  • the attribute screening module is used to use the seismic data and logging data of the target interval to analyze the correlation between different types of seismic attributes of the target interval and the reservoir parameters. Select the dominant seismic attribute from the attributes;
  • the waveform classification module is used to classify the seismic waveforms of the target interval according to the waveform characteristics by using the preset waveform classification network model based on the dominant seismic attributes, and obtain the waveform classification results; wherein, different types of waveforms correspond to different geological features;
  • the model building module is used to construct different deep neural network models corresponding to different geological features with seismic attributes as input, reservoir parameters as output, and waveform classification results as constraints;
  • a model training module for using the seismic data and logging data of the target section as training data and prediction data to train the different deep neural network models to optimize the model parameters of each deep neural network model;
  • the model fusion module is used to fuse different trained deep neural network models into a set of spatially varying neural network prediction models
  • the parameter prediction module is used to predict the reservoir parameters of the target interval by using a set of spatially varying neural network prediction models.
  • the present disclosure also provides a computer storage medium, characterized in that a computer program executable by a processor is stored therein, and when the computer program is executed by the processor, the above-mentioned geological feature constraint-based algorithm is implemented. Reservoir parameter prediction method.
  • the present disclosure further provides a computer device, characterized in that it includes a memory and a processor, and the processor is configured to execute a computer program stored in the memory, so as to implement the above geological feature constraint-based algorithm. Reservoir parameter prediction method.
  • the violent video classification technology incorporating internal and external knowledge provided by the present disclosure has the following advantages or beneficial effects:
  • the present disclosure adopts the LSTM-RNN neural network model to describe the nonlinear mapping relationship between seismic attributes and reservoir parameters, which not only considers the up-down correlation of seismic data and the up-down correlation of logging data, but also takes into account the seismic data.
  • the time series characteristics of the data and logging data establish a more accurate well-seismic mapping relationship than the prior art.
  • the present disclosure corresponds to a deep network model under the same geological feature (eg, sedimentary feature) by introducing waveform clustering, and by constructing a set of spatially varying neural network prediction models, with multi-type seismic attribute data as input, and geological features as Constraints, different network models are used to predict reservoir parameters under different waveform characteristics, which effectively improves the prediction accuracy.
  • geological feature eg, sedimentary feature
  • the present disclosure is a nonlinear reservoir parameter prediction technology based on geological feature constraints, which can realize direct prediction of reservoir parameters, especially in the depth domain, and improve the prediction accuracy and spatial stability of reservoir parameters.
  • the present disclosure helps to further improve Drilling success rate, reduce oilfield exploration and development costs, and improve oilfield production efficiency.
  • FIG. 1 is a schematic flowchart of a method for predicting reservoir parameters based on geological feature constraints according to Embodiment 1 of the present disclosure
  • FIG. 2 is a schematic diagram of the SOM unsupervised clustering network model in the method for predicting reservoir parameters according to Embodiment 1 of the present disclosure
  • FIG. 3 is a schematic diagram of the LSTM-RNN cyclic neural network model in the method for predicting reservoir parameters according to Embodiment 1 of the present disclosure
  • FIG. 4 is a schematic diagram of the forget gate in the LSTM-RNN cyclic neural network model according to the first embodiment of the present disclosure
  • FIG. 5 is a schematic diagram of an incoming gate in the LSTM-RNN cyclic neural network model according to Embodiment 1 of the present disclosure
  • FIG. 6 is a schematic diagram of an output gate in the LSTM-RNN cyclic neural network model according to Embodiment 1 of the present disclosure
  • FIG. 7 is a schematic diagram of the spatial variation coefficient in the construction of the spatial variation neural network prediction model set according to the first embodiment of the present disclosure
  • FIG. 8 is a schematic diagram of waveform classification input data according to Embodiment 2 of the present disclosure.
  • FIG. 9 is a schematic diagram of the waveform classification result of the second embodiment of the present disclosure along the O72 slice;
  • FIG. 10 is a schematic diagram of the input data of the deep neural network according to the second embodiment of the present disclosure.
  • FIG. 11 is a schematic diagram of constructing a deep neural network model according to Embodiment 2 of the present disclosure.
  • FIG. 12( a ) is a schematic diagram of slices along layers of a multi-model elastic parameter prediction result based on a deep neural network according to Embodiment 2 of the present disclosure
  • Fig. 12(b) is a schematic diagram of slice along the layer of the prediction result of the elastic parameter of a single model based on the deep neural network according to the second embodiment of the present disclosure
  • Fig. 12(c) is a schematic diagram of slice slices along the slice of the time domain inversion result of the second embodiment of the present disclosure
  • Fig. 12(d) is a schematic diagram of the engineering development and deployment scheme of the second embodiment of the present disclosure.
  • Fig. 13(a) is a comparison diagram of the original logging curve of well PU_IA and the multi-model prediction result according to the second embodiment of the present disclosure
  • Fig. 13(b) is a comparison diagram of the original logging curve of well PU_IB and the multi-model prediction result according to the second embodiment of the present disclosure
  • Fig. 13(c) is a comparison diagram of the original logging curve of well PU_IC and the multi-model prediction result according to the second embodiment of the present disclosure
  • Fig. 13(d) is a comparison diagram of the original logging curve of the PU_IC well and the prediction result of the single model according to the second embodiment of the present disclosure.
  • the present disclosure proposes a depth-domain reservoir parameter direct prediction technology based on geological feature constraints, so as to improve the In particular, the prediction accuracy of reservoir parameters in the depth domain improves the stability of spatial prediction, and provides a reasonable understanding and high-precision data for subsequent drilling and reservoir simulation to support efficient exploration and development.
  • the core idea of the present disclosure is: for example, in different depositional environments, using the same model for prediction may lead to low prediction accuracy, by introducing waveform clustering, under the same depositional characteristics, deep network is used to predict reservoir parameters , to improve the prediction accuracy.
  • the flow of the main method is shown in Figure 1.
  • the first step is to establish a macro-geological feature zone.
  • the seismic attributes with high reliability are used as the division and basis for the classification of waveform features, and also provide the data basis for subsequent reservoir parameters; then, combined with the automatic clustering algorithm based on SOM unsupervised learning, the automatic division of waveform features is realized, and the waveform classification
  • the results are used as the basis for geological feature zoning to characterize different geological features; then, different reservoir parameter prediction models are constructed according to different geological features.
  • LSTM-RNN - Recurrent Neural Network
  • the method for predicting reservoir parameters based on geological feature constraints mainly includes the following steps.
  • the correlation between different types of seismic attributes of the target interval and the reservoir parameters is determined through intersection analysis.
  • the seismic attributes whose correlation exceeds the preset correlation threshold are selected as the dominant seismic attributes; then, for each dominant seismic attribute, the data of the seismic attribute is decomposed and reconstructed by singular spectrum analysis, wherein, In the reconstructed sequence, the sequence components whose contribution degree is higher than the preset contribution degree threshold are retained as the dominant component of the dominant seismic attribute according to the contribution degree of the seismic attribute.
  • the decomposed and reconstructed dominant seismic attributes will be used for waveform cluster analysis and processing in step S200.
  • the seismic data and logging data can be pre-processed first. For example, smooth the logging data so that the spectrum of the smoothed logging data matches the spectrum of the seismic data; normalize the matched seismic data and logging data; The bottom is the boundary, and the seismic data and logging data belonging to the target interval are intercepted from the normalized seismic data and logging data. Then, different deep neural network models are trained using the seismic data and logging data belonging to the target interval to optimize the model parameters of each deep neural network model.
  • Step S100 is a seismic attribute optimization technique based on intersection analysis and singular spectrum analysis.
  • the intersection analysis of different types of seismic attributes and reservoir parameters of the target interval is first carried out, and attributes with higher correlation or contribution are selected.
  • the optimized seismic attributes are represented as one-dimensional data, and a trajectory matrix is constructed.
  • the trajectory matrix is further decomposed and reconstructed, and the different components and different components of the attributes are rearranged according to their contribution degrees.
  • the dominant earthquake is determined.
  • the dominant component of the attribute provides a data basis for subsequent waveform classification and direct prediction of reservoir parameters.
  • the specific algorithm of singular spectrum analysis is as follows:
  • Embedding representing preferred attribute data as one-dimensional data: [x 1 , x 2 , ..., x N ]
  • N is the sequence length
  • the eigenvector U m corresponding to ⁇ m reflects the evolution of the time series.
  • X i represents the i-th column of the trajectory matrix X, Indicates the weight of the time evolution type reflected by Xi in the period of Xi +1 , xi +2 , ..., xi+L of the original sequence.
  • the signal is reconstructed through the time empirical orthogonal function and the time principal component.
  • the specific reconstruction process is as follows:
  • the reconstructed sequence is equal to the original sequence, namely:
  • the dominant attributes and the main components of the dominant attributes are obtained, which provides a data basis for subsequent reservoir prediction.
  • the SOM unsupervised clustering algorithm (Fig. 2) is used to realize the automatic division of waveform features, and the earthquake multi-attribute is selected as the input data, and the SOM unsupervised network training model and topology are designed. Output waveform classification results to provide constraint data for subsequent reservoir parameter prediction.
  • the specific algorithm of SOM is as follows:
  • Each node randomly initializes its own parameters.
  • the number of parameters for each node is the same as the dimension of the input data.
  • the construction of different deep neural networks with waveform features is further carried out. Since the seismic data has the characteristics of time series signals, and the logging data also has a certain correlation in the vertical direction, the LSTM-RNN (Long Short-Term Memory-Recurrent Neural Network) is preferred to construct a nonlinear multi-network prediction model under different geological characteristics (Fig. 3). ).
  • LSTM-RNN Long Short-Term Memory-Recurrent Neural Network
  • FIG. 3 The schematic diagram of the LSTM-RNN recurrent neural network model is shown in Figure 3.
  • An LSTM unit is composed of three threshold structures and one state vector transmission line.
  • the thresholds are the forget gate, the incoming gate, and the output gate.
  • the state vector transmission line is responsible for long-term memory. , only do some simple linear operations; 3 gates are responsible for the selection of short-term memory, and delete or add operations to the input vector through the threshold setting.
  • the forget gate ( Figure 4) is implemented by a sigmoid neural layer, whose role is to decide what information to let through the unit. 0 means "let no information through”, 1 means "let all information through”.
  • the role of the incoming gate ( Figure 5) is to decide how much new information to add to the cell state.
  • the implementation of the incoming gate requires two steps: first, a sigmod layer decides which information needs to be updated; a tanh layer generates an alternative to update content; in the next step, the two departments are combined by vector dot product to update the state of the unit.
  • the function of the output gate ( Figure 6) is to output the final result.
  • the implementation of the output gate requires two steps: first, a sigmoid layer is used to determine which part of the information will be output; then, the state vector is passed through a tanh layer, and then the tanh layer is passed. The output of the sigmoid layer is multiplied by the weight calculated by the sigmoid layer, so that the final output result is obtained.
  • i is the input gate
  • is the logical sigmoid function
  • W xi , W hi , and W ci represent the weight matrix between the input feature vector, the hidden layer unit, the unit activation vector and the input gate, respectively
  • b i is the bias of the input gate.
  • f is the forget gate
  • W xf , W hf , W cf represent the weight matrix between the input feature vector, the hidden layer unit, the unit activation vector and the forget gate, respectively
  • b f is the bias of the forget gate
  • C is the Unit activation vector
  • W xc , W hc are the input feature vector, the weight matrix between the hidden layer unit and the unit activation vector, respectively, the weight matrix is a diagonal matrix
  • b c is the output gate offset value
  • o is the output Gate
  • W xo , W ho , W co represent the weight matrix between the input feature vector, hidden layer unit, unit activation vector and the output gate, respectively
  • b f is the bias of the forget gate
  • t as a subscript represents the sampling time
  • tanh is the activation function.
  • the input layer is the multi-attribute data next to the well
  • the output layer is the corresponding logging elastic parameters, such as the longitudinal wave velocity
  • the hidden layer is composed of: LSTM unit, full-connected layer, dropout layer, and regression layer, among which: LSTM unit is used for The time series features of logging data and seismic data are preserved; the full-connected layer is used as a classifier for the entire training network; the dropout layer is used to alleviate the occurrence of overfitting during network training and has a regularization effect; the regression layer is used as the network The output of the trained model.
  • w is the spatial variation coefficient
  • v 1 is the seismic trace of the neural network model that has been constructed
  • v 2 is the seismic trace of the neural network model to be constructed
  • w c represents the seismic trace of the neural network model that has been constructed and the seismic trace of the neural network model to be constructed.
  • the interpolation coefficient of the similarity of the trace waveform w d represents the interpolation coefficient of the distance between the seismic trace of the neural network model that has been constructed and the seismic trace of the neural network model to be constructed
  • c 12 represents the correlation between v 1 and v 2
  • d 12 represents v the distance between 1 and v2 , and represent the spatial positions of v 1 and v 2 , respectively
  • is the adjustment factor
  • ⁇ c and ⁇ d are the exponential factors.
  • V p represents the reservoir parameters
  • f k (x 1 , x 2 ,...x N ) represents the neural network prediction model corresponding to the kth geological feature
  • wk , i, j represent the kth geological feature corresponding
  • the spatial variation coefficients of the neural network prediction model, x 1 , x 2 , ... x N represent different types of seismic attributes.
  • This area is a clastic rock reservoir type, and two sets of reservoirs are developed, namely O72 and O73 layers, O72 layer is turbidite channel sheet sandstone, the development of the whole area is stable, there are 3 effective logging wells in this area, respectively
  • PU_IA well, PU_IB well, PU_IC well Firstly, multiple attributes are optimized based on intersection analysis and singular spectrum analysis technology (Fig. 8). The preferred input attributes are: envelope attribute, relative wave impedance, and instantaneous amplitude attribute. Combined with SOM unsupervised clustering algorithm, waveform classification is performed (Fig. 9).
  • the waveforms are divided into three categories: weak energy, medium energy, and strong energy.
  • the three corresponding wells are PU_IC well, PU_IB well, and PU_IA well.
  • the deep neural network is trained by waveform features, and the preferred input data (Fig. 10) include: seismic trace, envelope property, thin layer factor, relative wave impedance, Hilbert property, instantaneous frequency, dominant frequency and the instantaneous phase attribute, the output data is: longitudinal wave velocity, a 5-layer deep neural network is designed (Fig. 11), the prediction model is constructed, the waveform classification result is used as the constraint data, and the multi-model elastic parameter prediction based on the deep recurrent neural network is finally realized.
  • the direct prediction technology of reservoir parameters based on LSTM-RNN cyclic neural network is developed, which realizes the direct prediction of reservoir parameters based on the set of spatially varying neural network prediction models, and effectively maintains the geological stratigraphic structure.
  • the prediction accuracy of reservoir parameters is further improved.
  • the present embodiment provides a reservoir parameter prediction device, which is characterized by comprising:
  • the attribute screening module is used to use the seismic data and logging data of the target interval to analyze the correlation between different types of seismic attributes of the target interval and the reservoir parameters. Select the dominant seismic attribute from the attributes;
  • the waveform classification module is used to classify the seismic waveforms of the target interval according to the waveform characteristics by using the preset waveform classification network model based on the dominant seismic attributes, and obtain the waveform classification results; wherein, different types of waveforms correspond to different geological features;
  • the model building module is used to construct different deep neural network models corresponding to different geological features with seismic attributes as input, reservoir parameters as output, and waveform classification results as constraints;
  • a model training module for using the seismic data and logging data of the target interval as training data and prediction data to train the different deep neural network models to optimize the model parameters of each deep neural network model;
  • a model fusion module used to fuse the trained different deep neural network models into a set of spatially varying neural network prediction models
  • the parameter prediction module is used to predict the reservoir parameters of the target interval by using a set of spatially varying neural network prediction models.
  • this embodiment provides a computer storage medium storing a computer program.
  • the computer storage medium when executed by one or more computer processors, implements the aforementioned method for predicting reservoir parameters.
  • the above-mentioned storage medium can be flash memory, hard disk, multimedia card, card-type memory (for example, SD or DX memory, etc.), random access memory (RAM), static random access memory (SRAM), read only memory (ROM), electrically erasable memory
  • RAM random access memory
  • SRAM static random access memory
  • ROM read only memory
  • EEPROM programmable read-only memory
  • PROM programmable read-only memory
  • magnetic memory magnetic disk, optical disk, server, App (Application, application) application mall and so on.
  • this embodiment provides a computer device including a memory and a processor.
  • a computer program is stored in the memory, and when the computer program is executed by the processor, the aforementioned method for predicting reservoir parameters is executed.
  • the processor may be an Application Specific Integrated Circuit (ASIC), a Digital Signal Processor (DSP), a Digital Signal Processing Device (DSPD), or a Programmable Logic Device (Programmable Logic Device).
  • ASIC Application Specific Integrated Circuit
  • DSP Digital Signal Processor
  • DSPD Digital Signal Processing Device
  • PLD Programmable Logic Device
  • FPGA Field Programmable Gate Array
  • controller microcontroller
  • microprocessor or other electronic components.
  • the reservoir parameter prediction method described in any one of 5.
  • the memory can be implemented by any type of volatile or non-volatile storage device or their combination, such as Static Random Access Memory (SRAM), Electrically Erasable Programmable Read-Only Memory (Electrically Erasable) Programmable Read-Only Memory (EEPROM for short), Erasable Programmable Read-Only Memory (EPROM), Programmable Read-Only Memory (PROM), Read-Only Memory ( Read-Only Memory, referred to as ROM), magnetic memory, flash memory, magnetic disk or optical disk.
  • SRAM Static Random Access Memory
  • EEPROM Electrically Erasable Programmable Read-Only Memory
  • EPROM Erasable Programmable Read-Only Memory
  • PROM Programmable Read-Only Memory
  • ROM Read-Only Memory
  • magnetic memory flash memory
  • flash memory magnetic disk or optical disk.
  • each block in the flowchart or block diagrams may represent a module, segment, or portion of code that contains one or more functions for implementing the specified logical function(s) executable instructions. It should also be noted that, in some alternative implementations, the functions noted in the block may occur out of the order noted in the figures.
  • each functional module in each embodiment of the present disclosure may be integrated together to form an independent part, or each module may exist alone, or two or more modules may be integrated to form an independent part.
  • the functions are implemented in the form of software function modules and sold or used as independent products, they can be stored in a computer-readable storage medium.
  • the technical solutions of the present disclosure can be embodied in the form of software products in essence, or the parts that make contributions to the prior art or the parts of the technical solutions.
  • the computer software products are stored in a storage medium, including Several instructions are used to cause a computer device (which may be a personal computer, a server, or a network device, etc.) to execute all or part of the steps of the methods described in various embodiments of the present disclosure.

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Abstract

A geological feature constraint-based reservoir parameter prediction method, an apparatus, a computer storage medium and a computer device. Said method comprises: selecting dominant seismic attributes according to the relevance between different types of seismic attributes of a target stratum and reservoir parameters (S100); on the basis of the dominant seismic attributes, classifying seismic waveforms of the target stratum using a preset waveform classification network model according to waveform features, so as to obtain a waveform classification result (S200); taking the waveform classification result as a constraint, constructing different deep neural network models corresponding to different geological features (S300); fusing different trained deep neural network models into a spatially varying neural network prediction model set (S500); and predicting the reservoir parameters of the target stratum using the spatially varying neural network prediction model set (S600).

Description

基于地质特征约束的储层参数预测方法、装置和存储介质Reservoir parameter prediction method, device and storage medium based on geological feature constraints
本公开要求享有2020年9月7号提交的名称为“基于地质特征约束的储层参数预测方法、装置和存储介质”的中国专利申请CN 202010928912.0和名称为“储层参数预测方法、装置、存储介质及电子设备”的中国专利申请CN 202010931370.2的优先权,其全部内容通过引用并入本文中。The present disclosure claims to enjoy the Chinese patent application CN 202010928912.0 entitled "Reservoir parameter prediction method, device and storage medium based on geological feature constraints" filed on September 7, 2020 and the title of "Reservoir parameter prediction method, device, storage medium". Priority of Chinese Patent Application CN 202010931370.2 for "Media and Electronic Devices", the entire contents of which are incorporated herein by reference.
技术领域technical field
本公开属于地球物理勘探技术领域,尤其涉及一种基于地质特征约束的储层参数预测方法、装置和计算机存储介质以及计算机设备。The present disclosure belongs to the technical field of geophysical exploration, and in particular, relates to a method, device, computer storage medium and computer equipment for predicting reservoir parameters based on geological feature constraints.
背景技术Background technique
随着叠前深度偏移处理技术的发展及其在地震资料处理中日益广泛的应用,直接在深度域进行储层参数预测具有十分重要的意义。针对深度域地震储层预测技术,国内外主要的方法技术主要有三种:一是以Hampson-Russell软件公司部分模块、Geophysical Insight公司、BGP公司为代表的映射类方法,该技术主要通过神经网络建立多属性数据与测井数据的一个综合性的网络映射关系,进行储层参数直接预测,但是,在不同沉积环境下,用同一个模型预测可能会出现预测精度低的问题,同时,缺少地质特征约束,预测模型泛化能力差,预测结果容易过拟合,不符合宏观地质规律;二是以Paradigm公司、中石油西北分院、胜利油田为代表的基于深度域“子波”提取的反演类方法,该技术主要通过深度域“子波”提取,结合常规的反演技术,开展弹性参数直接预测,但是基于深度域数据的理论模型尚未建立,因此基础理论性不足;三是以Jason公司为代表的基于高精度速度体转换的深度域储层参数预测方法,该方法将深度域数据转化为时间域数据,进行常规储层参数预测,但是深时转化存在一定的转化累积误差,且费时费力,不利于提高储层预测精度。With the development of prestack depth migration processing technology and its increasingly widespread application in seismic data processing, it is of great significance to directly predict reservoir parameters in the depth domain. For depth domain seismic reservoir prediction technology, there are three main methods and technologies at home and abroad: one is the mapping method represented by some modules of Hampson-Russell software company, Geophysical Insight company, and BGP company. This technology is mainly established through neural network. A comprehensive network mapping relationship between multi-attribute data and well logging data enables direct prediction of reservoir parameters. However, in different depositional environments, using the same model for prediction may have problems of low prediction accuracy, and at the same time, lack of geological features Constraints, the generalization ability of the prediction model is poor, and the prediction results are easy to over-fit, which does not conform to the macroscopic geological laws; the second is an inversion method based on the extraction of "wavelets" in the depth domain, represented by Paradigm Company, PetroChina Northwest Branch, and Shengli Oilfield. , this technology mainly uses depth domain "wavelet" extraction, combined with conventional inversion technology, to carry out direct prediction of elastic parameters, but the theoretical model based on depth domain data has not been established, so the basic theory is insufficient; the third is represented by Jason company The depth-domain reservoir parameter prediction method based on high-precision velocity volume transformation, this method converts the depth-domain data into time-domain data for conventional reservoir parameter prediction, but the deep-time transformation has a certain transformation cumulative error, and it is time-consuming and labor-intensive. It is not conducive to improving the reservoir prediction accuracy.
发明内容SUMMARY OF THE INVENTION
针对上述技术问题,本公开提出了一种基于地质特征约束的储层参数预测方法、装置和计算机存储介质以及计算机设备。本公开In view of the above technical problems, the present disclosure proposes a method, device, computer storage medium, and computer equipment for predicting reservoir parameters based on geological feature constraints. this disclosure
根据本公开的第一方面,本公开提供的一种基于地质特征约束的储层参数预测方法,包括以下步骤:According to the first aspect of the present disclosure, the present disclosure provides a method for predicting reservoir parameters based on geological feature constraints, comprising the following steps:
S100、根据目标层段的不同类型的地震属性与储层参数之间的相关度,从不同类型的地震属性中选出优势地震属性;S100, selecting a dominant seismic attribute from different types of seismic attributes according to the correlation between different types of seismic attributes of the target interval and reservoir parameters;
S200、基于优势地震属性,利用预设的波形分类网络模型将目标层段的地震波形按照波形特征进行分类,获得波形分类结果;其中,不同类型的波形对应表征不同的地质特征;S200 , using a preset waveform classification network model to classify the seismic waveforms of the target interval according to waveform characteristics based on the dominant seismic attributes, to obtain a waveform classification result; wherein, different types of waveforms correspond to different geological features;
S300、以地震属性为输入,以储层参数为输出,以波形分类结果为约束,构建不同的地质特征所对应的不同的深度神经网络模型;S300 , taking seismic attributes as input, taking reservoir parameters as output, and taking waveform classification results as constraints, constructing different deep neural network models corresponding to different geological features;
S400、利用目标层段的地震数据和测井数据作为训练数据和预测数据,对所述不同的深度神经网络模型进行训练,以优化每个深度神经网络模型的模型参数;S400, using the seismic data and logging data of the target interval as training data and prediction data, to train the different deep neural network models to optimize the model parameters of each deep neural network model;
S500、将训练好的不同的深度神经网络模型融合成空间变化神经网络预测模型集合;S500. Integrate different trained deep neural network models into a set of spatially varying neural network prediction models;
S600、利用空间变化神经网络预测模型集合对目标层段的储层参数进行预测。S600. Use a set of spatially varying neural network prediction models to predict the reservoir parameters of the target interval.
根据本公开的一个实施例,上述步骤S100包括以下步骤:According to an embodiment of the present disclosure, the above step S100 includes the following steps:
利用目标层段的地震数据和测井数据,通过交汇分析确定目标层段的不同类型的地震属性与储层参数之间的相关度,从不同类型的地震属性中选出相关度超过预设相关度阈值的地震属性,作为优势地震属性;Using the seismic data and logging data of the target interval, the correlation between different types of seismic attributes of the target interval and the reservoir parameters is determined through intersection analysis, and the correlation degree is selected from different types of seismic attributes that exceed the preset correlation. The seismic attribute of the degree threshold is regarded as the dominant seismic attribute;
对于每一个优势地震属性,通过奇异谱分析对该地震属性的数据进行分解和重构,其中,在重构后的序列中按照对该地震属性的贡献度的大小保留贡献度高于预设贡献度阈值的序列分量,作为该优势地震属性的优势分量。For each dominant seismic attribute, the data of the seismic attribute is decomposed and reconstructed by singular spectrum analysis, wherein in the reconstructed sequence, the contribution degree is kept higher than the preset contribution according to the contribution degree of the seismic attribute The sequence component of the degree threshold is used as the dominant component of the dominant seismic attribute.
根据本公开的一个实施例,上述步骤S200中,所述波形分类网络模型为基于SOM无监督聚类算法设计的SOM无监督网络模型,该网络模型包括地震属性输入层和分类结果输出层。According to an embodiment of the present disclosure, in the above step S200, the waveform classification network model is an SOM unsupervised network model designed based on the SOM unsupervised clustering algorithm, and the network model includes a seismic attribute input layer and a classification result output layer.
根据本公开的一个实施例,所述地质特征包括沉积特征。According to one embodiment of the present disclosure, the geological features comprise sedimentary features.
根据本公开的一个实施例,上述步骤S300中,每个所述深度神经网络模型 为LSTM-RNN循环神经网络模型,该网络模型包括地震属性输入层和储层参数输出层以及位于地震属性输入层与储层参数输出层之间的隐藏层;其中,所述隐藏层包括:According to an embodiment of the present disclosure, in the above step S300, each of the deep neural network models is an LSTM-RNN recurrent neural network model, and the network model includes a seismic attribute input layer, a reservoir parameter output layer, and a seismic attribute input layer. and the hidden layer between the reservoir parameter output layer; wherein, the hidden layer includes:
LSTM单元,用于保留地震数据和测井数据的时序特征;LSTM unit to preserve the time series characteristics of seismic data and logging data;
full-connected层,用作训练网络模型的分类器full-connected layer, used as a classifier to train the network model
dropout层,用于缓解网络模型训练过程中的过拟合现象;The dropout layer is used to alleviate the overfitting phenomenon in the network model training process;
regression层,用作训练网络模型的输出。regression layer, which is used as the output for training the network model.
根据本公开的一个实施例,所述步骤S400进一步包括:According to an embodiment of the present disclosure, the step S400 further includes:
对测井数据进行平滑处理,使得平滑处理后的测井数据的频谱与地震数据的频谱相互匹配;Smoothing the logging data, so that the spectrum of the smoothed logging data matches the spectrum of the seismic data;
对匹配后的地震数据和测井数据进行归一化处理;Normalize the matched seismic data and logging data;
以目的层段的顶底为边界,从归一化处理后的地震数据和测井数据中截取属于目的层段范围内的地震数据和测井数据;Taking the top and bottom of the target interval as the boundary, intercept the seismic data and logging data belonging to the target interval from the normalized seismic data and logging data;
利用属于目的层段范围内的地震数据和测井数据对不同的深度神经网络模型进行训练,以优化每个深度神经网络模型的模型参数。Different deep neural network models are trained using seismic data and logging data belonging to the target interval to optimize the model parameters of each deep neural network model.
根据本公开的一个实施例,上述步骤S500中,基于波形的相似性和空间距离确定每个训练好的深度神经网络模型在空间变化神经网络预测模型集合中的空间变化系数。According to an embodiment of the present disclosure, in the above step S500, the spatial variation coefficient of each trained deep neural network model in the spatial variation neural network prediction model set is determined based on the similarity of the waveforms and the spatial distance.
根据本公开的一个实施例,上述步骤S600中,按照下式,将训练好的不同的深度神经网络模型融合成空间变化神经网络预测模型集合:According to an embodiment of the present disclosure, in the above step S600, different trained deep neural network models are fused into a set of spatially varying neural network prediction models according to the following formula:
Figure PCTCN2021103487-appb-000001
Figure PCTCN2021103487-appb-000001
式中:V p代表储层参数,f k(x 1,x 2,…x N)代表第k种地质特征下的深度神经网络模型,w k,i,j代表第k种地质特征下的深度神经网络模型的空间变化系数,x 1,x 2,…x N代表不同类型的地震属性。 In the formula: V p represents the reservoir parameters, f k (x 1 , x 2 ,...x N ) represents the deep neural network model under the kth geological feature, wk , i, j represent the kth geological feature under the The spatial variation coefficients of the deep neural network model, x 1 , x 2 , … x N represent different types of seismic attributes.
根据本公开的一个实施例,按照下式,确定每个训练好的深度神经网络模型 在空间变化神经网络预测模型集合中的空间变化系数:According to an embodiment of the present disclosure, according to the following formula, determine the spatial variation coefficient of each trained deep neural network model in the spatial variation neural network prediction model set:
w=λw c+(1-λ)w d w=λw c +(1-λ)w d
Figure PCTCN2021103487-appb-000002
Figure PCTCN2021103487-appb-000002
Figure PCTCN2021103487-appb-000003
Figure PCTCN2021103487-appb-000003
w c=exp(-α cc 12 2) w c =exp(-α c c 12 2 )
w d=exp(-α dd 12 2) w d =exp(-α d d 12 2 )
式中:w为空间变化系数,v 1为已构建深度神经网络模型的地震道,v 2为待构建深度神经网络模型的地震道,w c表示已构建深度神经网络模型地震道与待构建深度神经网络模型地震道波形相似性的插值系数,w d表示已构建深度神经网络模型地震道与待构建深度神经网络模型地震道距离的插值系数,c 12表示v 1和v 2之间的相关性,d 12表示表示v 1和v 2之间的距离,
Figure PCTCN2021103487-appb-000004
Figure PCTCN2021103487-appb-000005
分别表示v 1和v 2的空间位置,λ为调节因子,α c和α d为指数因子。
In the formula: w is the spatial variation coefficient, v 1 is the seismic trace of the deep neural network model that has been constructed, v 2 is the seismic trace of the deep neural network model to be constructed, and w c represents the seismic trace of the deep neural network model that has been constructed and the depth to be constructed. The interpolation coefficient of the waveform similarity of the neural network model seismic trace, w d represents the interpolation coefficient of the distance between the seismic trace of the built deep neural network model and the seismic trace of the deep neural network model to be constructed, c 12 represents the correlation between v 1 and v 2 , d 12 represents the distance between v 1 and v 2 ,
Figure PCTCN2021103487-appb-000004
and
Figure PCTCN2021103487-appb-000005
represent the spatial positions of v 1 and v 2 , respectively, λ is the adjustment factor, and α c and α d are the exponential factors.
根据本公开的一个实施例,上述目的层段的储层参数包括目的层段的空间三维弹性参数体,所述方法还包括输出目的层段的空间三维弹性参数体的分布图。According to an embodiment of the present disclosure, the above-mentioned reservoir parameters of the target interval include a spatial three-dimensional elastic parameter volume of the target interval, and the method further includes outputting a distribution map of the spatial three-dimensional elastic parameter volume of the target interval.
根据本公开的第二方面,本公开还提供一种基于地质特征约束的储层参数预测装置,其特征在于,包括:According to a second aspect of the present disclosure, the present disclosure also provides a reservoir parameter prediction device based on geological feature constraints, characterized in that it includes:
属性筛选模块,用于利用目标层段的地震数据和测井数据,分析目标层段的不同类型的地震属性与储层参数之间的相关度,根据所述相关度的大小从不同类型的地震属性中选出优势地震属性;The attribute screening module is used to use the seismic data and logging data of the target interval to analyze the correlation between different types of seismic attributes of the target interval and the reservoir parameters. Select the dominant seismic attribute from the attributes;
波形分类模块,用于基于优势地震属性,利用预设的波形分类网络模型将目标层段的地震波形按照波形特征进行分类,获得波形分类结果;其中,不同类型的波形对应表征不同的地质特征;The waveform classification module is used to classify the seismic waveforms of the target interval according to the waveform characteristics by using the preset waveform classification network model based on the dominant seismic attributes, and obtain the waveform classification results; wherein, different types of waveforms correspond to different geological features;
模型构建模块,用于以地震属性为输入,以储层参数为输出,以波形分类结果为约束,构建不同的地质特征所对应的不同的深度神经网络模型;The model building module is used to construct different deep neural network models corresponding to different geological features with seismic attributes as input, reservoir parameters as output, and waveform classification results as constraints;
模型训练模块,用于利用目标层段的地震数据和测井数据作为训练数据和预测数据,对所述不同的深度神经网络模型进行训练,以优化每个深度神经网络模 型的模型参数;A model training module for using the seismic data and logging data of the target section as training data and prediction data to train the different deep neural network models to optimize the model parameters of each deep neural network model;
模型融合模块,用于将训练好的不同的深度神经网络模型融合成空间变化神经网络预测模型集合;The model fusion module is used to fuse different trained deep neural network models into a set of spatially varying neural network prediction models;
参数预测模块,用于利用空间变化神经网络预测模型集合对目标层段的储层参数进行预测。The parameter prediction module is used to predict the reservoir parameters of the target interval by using a set of spatially varying neural network prediction models.
根据本公开的第三方面,本公开还提供一种计算机存储介质,其特征在于,其中存储有可被处理器执行的计算机程序,该计算机程序在被处理器执行时实现上述基于地质特征约束的储层参数预测方法。According to a third aspect of the present disclosure, the present disclosure also provides a computer storage medium, characterized in that a computer program executable by a processor is stored therein, and when the computer program is executed by the processor, the above-mentioned geological feature constraint-based algorithm is implemented. Reservoir parameter prediction method.
根据本公开的第四方面,本公开还提供一种计算机设备,其特征在于,包括存储器和处理器,所述处理器用于执行所述存储器中存储的计算机程序,以实现上述基于地质特征约束的储层参数预测方法。According to a fourth aspect of the present disclosure, the present disclosure further provides a computer device, characterized in that it includes a memory and a processor, and the processor is configured to execute a computer program stored in the memory, so as to implement the above geological feature constraint-based algorithm. Reservoir parameter prediction method.
与现有技术相比,本公开提供的融入内外部知识的暴力视频分类技术具有如下优点或有益效果:Compared with the prior art, the violent video classification technology incorporating internal and external knowledge provided by the present disclosure has the following advantages or beneficial effects:
1.本公开采用LSTM-RNN神经网络模型来描述地震属性与储层参数之间的非线性映射关系,既考虑了地震数据的上下关联性和测井数据的上下关联性,同时还兼顾了地震数据和测井数据的时序特征,建立了比现有技术更加准确的井震映射关系。1. The present disclosure adopts the LSTM-RNN neural network model to describe the nonlinear mapping relationship between seismic attributes and reservoir parameters, which not only considers the up-down correlation of seismic data and the up-down correlation of logging data, but also takes into account the seismic data. The time series characteristics of the data and logging data establish a more accurate well-seismic mapping relationship than the prior art.
2.本公开通过引入波形聚类,在同一地质特征(例如,沉积特征)下对应一个深度网络模型,通过构建空间变化神经网络预测模型集合,以多类型地震属性数据为输入,以地质特征为约束,在不同的波形特征下使用不同的网络模型进行储层参数预测,有效提高了预测精度。2. The present disclosure corresponds to a deep network model under the same geological feature (eg, sedimentary feature) by introducing waveform clustering, and by constructing a set of spatially varying neural network prediction models, with multi-type seismic attribute data as input, and geological features as Constraints, different network models are used to predict reservoir parameters under different waveform characteristics, which effectively improves the prediction accuracy.
3.本公开是基于地质特征约束的非线性储层参数预测技术,能够实现对尤其是深度域储层参数的直接预测,提高储层参数预测精度及空间稳定性本公开,有助于进一步提高钻井成功率,降低油田勘探开发成本,提高油田生产效益。3. The present disclosure is a nonlinear reservoir parameter prediction technology based on geological feature constraints, which can realize direct prediction of reservoir parameters, especially in the depth domain, and improve the prediction accuracy and spatial stability of reservoir parameters. The present disclosure helps to further improve Drilling success rate, reduce oilfield exploration and development costs, and improve oilfield production efficiency.
本公开的其他特征和优点将在随后的说明书中阐述,并且,部分的从说明书中变得显而易见,或者通过实施本公开而了解。本公开的目的和其他优点可通过在说明书、权利要求书以及附图中所指出的结构来实现和获得。Other features and advantages of the present disclosure will be set forth in the description that follows, and in part will be apparent from the description, or will be learned by practice of the present disclosure. The objectives and other advantages of the present disclosure may be realized and attained by the structure pointed out in the description, claims and drawings.
附图说明Description of drawings
附图1是本公开实施例一的基于地质特征约束的储层参数预测方法流程示意 图;1 is a schematic flowchart of a method for predicting reservoir parameters based on geological feature constraints according to Embodiment 1 of the present disclosure;
附图2是本公开实施例一的储层参数预测方法中的SOM无监督聚类网络模型示意图;2 is a schematic diagram of the SOM unsupervised clustering network model in the method for predicting reservoir parameters according to Embodiment 1 of the present disclosure;
附图3是本公开实施例一的储层参数预测方法中的LSTM-RNN循环神经网络模型示意图;3 is a schematic diagram of the LSTM-RNN cyclic neural network model in the method for predicting reservoir parameters according to Embodiment 1 of the present disclosure;
附图4是本公开实施例一的LSTM-RNN循环神经网络模型中的遗忘门示意图;FIG. 4 is a schematic diagram of the forget gate in the LSTM-RNN cyclic neural network model according to the first embodiment of the present disclosure;
附图5是本公开实施例一的LSTM-RNN循环神经网络模型中的传入门示意图;5 is a schematic diagram of an incoming gate in the LSTM-RNN cyclic neural network model according to Embodiment 1 of the present disclosure;
附图6是本公开实施例一的LSTM-RNN循环神经网络模型中的输出门示意图;6 is a schematic diagram of an output gate in the LSTM-RNN cyclic neural network model according to Embodiment 1 of the present disclosure;
附图7是本公开实施例一的构建空间变化神经网络预测模型集合中的空间变化系数的示意图;FIG. 7 is a schematic diagram of the spatial variation coefficient in the construction of the spatial variation neural network prediction model set according to the first embodiment of the present disclosure;
附图8是本公开实施例二的波形分类输入数据示意图;8 is a schematic diagram of waveform classification input data according to Embodiment 2 of the present disclosure;
附图9是本公开实施例二的波形分类结果沿O72切片示意图;9 is a schematic diagram of the waveform classification result of the second embodiment of the present disclosure along the O72 slice;
附图10是本公开实施例二的深度神经网络输入数据示意图;10 is a schematic diagram of the input data of the deep neural network according to the second embodiment of the present disclosure;
附图11是本公开实施例二的深度神经网络模型构建示意图;11 is a schematic diagram of constructing a deep neural network model according to Embodiment 2 of the present disclosure;
附图12(a)是本公开实施例二的基于深度神经网络的多模型弹性参数预测结果沿层切片示意图;FIG. 12( a ) is a schematic diagram of slices along layers of a multi-model elastic parameter prediction result based on a deep neural network according to Embodiment 2 of the present disclosure;
附图12(b)是本公开实施例二的基于深度神经网络的单模型弹性参数预测结果沿层切片示意图;Fig. 12(b) is a schematic diagram of slice along the layer of the prediction result of the elastic parameter of a single model based on the deep neural network according to the second embodiment of the present disclosure;
附图12(c)是本公开实施例二的时间域反演结果沿层切片示意图;Fig. 12(c) is a schematic diagram of slice slices along the slice of the time domain inversion result of the second embodiment of the present disclosure;
附图12(d)是本公开实施例二的工程开发部署方案示意图;Fig. 12(d) is a schematic diagram of the engineering development and deployment scheme of the second embodiment of the present disclosure;
附图13(a)是本公开实施例二的PU_IA井原始测井曲线与多模型预测结果对比图;Fig. 13(a) is a comparison diagram of the original logging curve of well PU_IA and the multi-model prediction result according to the second embodiment of the present disclosure;
附图13(b)是本公开实施例二的PU_IB井原始测井曲线与多模型预测结果对比图;Fig. 13(b) is a comparison diagram of the original logging curve of well PU_IB and the multi-model prediction result according to the second embodiment of the present disclosure;
附图13(c)是本公开实施例二的PU_IC井原始测井曲线与多模型预测结果对比图;Fig. 13(c) is a comparison diagram of the original logging curve of well PU_IC and the multi-model prediction result according to the second embodiment of the present disclosure;
附图13(d)是本公开实施例二的PU_IC井原始测井曲线与单模型预测结果 对比图。Fig. 13(d) is a comparison diagram of the original logging curve of the PU_IC well and the prediction result of the single model according to the second embodiment of the present disclosure.
具体实施方式detailed description
由于目前常见的深度域储层预测方法存在预测精度低、预测效率低以及不符合宏观地质特征等缺点,因此本公开提出了一种基于地质特征约束的深度域储层参数直接预测技术,以提高尤其深度域储层参数预测精度,提升空间预测稳定性,为后续钻井及油藏模拟提供合理的认识、高精度的数据,以支撑高效勘探开发。Due to the disadvantages of low prediction accuracy, low prediction efficiency, and incompatibility with macroscopic geological characteristics in the current common depth-domain reservoir prediction methods, the present disclosure proposes a depth-domain reservoir parameter direct prediction technology based on geological feature constraints, so as to improve the In particular, the prediction accuracy of reservoir parameters in the depth domain improves the stability of spatial prediction, and provides a reasonable understanding and high-precision data for subsequent drilling and reservoir simulation to support efficient exploration and development.
本公开的核心思想是:针对在例如不同沉积环境下,使用同一个模型预测可能会导致预测精度骗低的问题,通过引入波形聚类,在同一沉积特征下,采用深度网络进行储层参数预测,以提高预测精度。主要方法的流程如图1所示,首先是建立宏观地质特征分带,通过计算深度域动力学、运动学、几何学等多类型的属性,并比对宏观地质背景及测井数据,优选相关性高的地震属性,作为波形特征分类的划分及依据,也作为后续储层参数提供数据基础;然后,结合基于SOM无监督学习的自动聚类算法,实现对波形特征的自动划分,以波形分类结果作为地质特征分带依据来表征不同的地质特征;接着,按照不同地质特征构建不同的储层参数预测模型,在不同的地质分带下,结合测井数据和地震属性数据,利用长短时记忆-循环神经网络(LSTM-RNN)构建不同井位置处的非线性网络预测模型,通过不断调参、优化模型参数,使单点预测模型泛化、收敛;最后,构建空间变化神经网络预测模型集合,以多类型地震属性数据为输入,以地质特征为约束,在不同的波形特征下使用不同的网络模型进行储层参数预测,最终获得三维空间参数体的综合预测结果。The core idea of the present disclosure is: for example, in different depositional environments, using the same model for prediction may lead to low prediction accuracy, by introducing waveform clustering, under the same depositional characteristics, deep network is used to predict reservoir parameters , to improve the prediction accuracy. The flow of the main method is shown in Figure 1. The first step is to establish a macro-geological feature zone. By calculating the depth domain dynamics, kinematics, geometry and other types of attributes, and comparing the macro-geological background and logging data, the relevant The seismic attributes with high reliability are used as the division and basis for the classification of waveform features, and also provide the data basis for subsequent reservoir parameters; then, combined with the automatic clustering algorithm based on SOM unsupervised learning, the automatic division of waveform features is realized, and the waveform classification The results are used as the basis for geological feature zoning to characterize different geological features; then, different reservoir parameter prediction models are constructed according to different geological features. - Recurrent Neural Network (LSTM-RNN) constructs nonlinear network prediction models at different well positions, and makes the single-point prediction model generalize and converge by continuously adjusting and optimizing model parameters; finally, constructing a set of spatially varying neural network prediction models , taking multi-type seismic attribute data as input and geological features as constraints, using different network models to predict reservoir parameters under different waveform characteristics, and finally obtain comprehensive prediction results of three-dimensional spatial parameter volume.
为使本公开的目的,技术方案和优点更加清楚,以下结合实施例和附图对本公开作进一步的详细说明,借此对本公开如何应用技术手段解决技术问题,并达成技术效果的实现过程能充分理解并据以实施。In order to make the purpose, technical solutions and advantages of the present disclosure clearer, the present disclosure will be described in further detail below with reference to the embodiments and the accompanying drawings, thereby how the present disclosure can apply technical means to solve technical problems and achieve the realization process of technical effects. Understand and implement accordingly.
实施例一Example 1
如图1所示,本公开提供的基于地质特征约束的储层参数预测方法主要包括以下步骤。As shown in FIG. 1 , the method for predicting reservoir parameters based on geological feature constraints provided by the present disclosure mainly includes the following steps.
S100、根据目标层段的不同类型的地震属性与储层参数之间的相关度,从不 同类型的地震属性中选出优势地震属性。S100. Select a dominant seismic attribute from different types of seismic attributes according to the correlation between different types of seismic attributes of the target interval and reservoir parameters.
具体而言,首先利用目标层段的地震数据和测井数据,通过交汇分析确定目标层段的不同类型的地震属性与储层参数之间的相关度,根据所述相关度的大小从不同类型的地震属性中选出相关度超过预设相关度阈值的地震属性,作为优势地震属性;然后,对于每一个优势地震属性,通过奇异谱分析对该地震属性的数据进行分解和重构,其中,在重构后的序列中按照对该地震属性的贡献度的大小保留贡献度高于预设贡献度阈值的序列分量,作为该优势地震属性的优势分量。Specifically, first, using the seismic data and logging data of the target interval, the correlation between different types of seismic attributes of the target interval and the reservoir parameters is determined through intersection analysis. The seismic attributes whose correlation exceeds the preset correlation threshold are selected as the dominant seismic attributes; then, for each dominant seismic attribute, the data of the seismic attribute is decomposed and reconstructed by singular spectrum analysis, wherein, In the reconstructed sequence, the sequence components whose contribution degree is higher than the preset contribution degree threshold are retained as the dominant component of the dominant seismic attribute according to the contribution degree of the seismic attribute.
经过分解和重构的优势地震属性将被用于步骤S200的波形聚类分析和处理。The decomposed and reconstructed dominant seismic attributes will be used for waveform cluster analysis and processing in step S200.
S200、基于优势地震属性,利用预设的波形分类网络模型将目标层段的地震波形按照波形特征进行分类,获得波形分类结果;其中,不同的波形对应于不同的地质特征。S200. Based on the dominant seismic attributes, use a preset waveform classification network model to classify the seismic waveforms of the target interval according to the waveform features, and obtain a waveform classification result; wherein, different waveforms correspond to different geological features.
S300、以地震属性为输入,以储层参数为输出,以波形分类结果为约束,构建不同的地质特征所对应的不同的深度神经网络模型。S300 , using seismic attributes as input, reservoir parameters as output, and waveform classification results as constraints, construct different deep neural network models corresponding to different geological features.
S400、利用目标层段的地震数据和测井数据作为训练数据和预测数据,对不同的深度神经网络模型进行训练,以优化每个深度神经网络模型的模型参数。S400. Use the seismic data and logging data of the target interval as training data and prediction data to train different deep neural network models to optimize model parameters of each deep neural network model.
在具体应用时,为了进一步提高预测结果的精确度,还可以首先对地震数据和测井数据做一些预处理。例如,对测井数据进行平滑处理,使得平滑处理后的测井数据的频谱与地震数据的频谱相互匹配;对匹配后的地震数据和测井数据进行归一化处理;以目的层段的顶底为边界,从归一化处理后的地震数据和测井数据中截取属于目的层段范围内的地震数据和测井数据。然后,再利用属于目的层段范围内的地震数据和测井数据对不同的深度神经网络模型进行训练,以优化每个深度神经网络模型的模型参数。In specific applications, in order to further improve the accuracy of the prediction results, the seismic data and logging data can be pre-processed first. For example, smooth the logging data so that the spectrum of the smoothed logging data matches the spectrum of the seismic data; normalize the matched seismic data and logging data; The bottom is the boundary, and the seismic data and logging data belonging to the target interval are intercepted from the normalized seismic data and logging data. Then, different deep neural network models are trained using the seismic data and logging data belonging to the target interval to optimize the model parameters of each deep neural network model.
S500、将训练好的不同的深度神经网络模型融合成空间变化神经网络预测模型集合;其中,利用波形相似性和空间距离确定每个训练好的深度神经网络模型在空间变化神经网络预测模型集合中的空间变化系数。S500. Integrate different trained deep neural network models into a set of spatially varying neural network prediction models; wherein, waveform similarity and spatial distance are used to determine whether each trained deep neural network model is in the set of spatially varying neural network prediction models The spatial variation coefficient of .
S600、利用空间变化神经网络预测模型集合对目标层段的储层参数进行预测。S600. Use a set of spatially varying neural network prediction models to predict the reservoir parameters of the target interval.
下面对各个步骤展开详细说明。Each step is described in detail below.
(1)步骤S100是基于交汇分析和奇异谱分析的地震属性优选技术。在该步 骤中,首先开展目标层段的不同类型的地震属性与储层参数的交汇分析,优选相关性或贡献度较高的属性。然后,将优选后的地震属性表示成一维数据,并构造出轨迹矩阵,进一步将轨迹矩阵进行分解、重构,按贡献度大小将属性的不同成分、不同分量进行重排,最终,确定优势地震属性的优势分量,为后续波形分类和储层参数直接预测提供数据基础。奇异谱分析的具体算法如下:(1) Step S100 is a seismic attribute optimization technique based on intersection analysis and singular spectrum analysis. In this step, the intersection analysis of different types of seismic attributes and reservoir parameters of the target interval is first carried out, and attributes with higher correlation or contribution are selected. Then, the optimized seismic attributes are represented as one-dimensional data, and a trajectory matrix is constructed. The trajectory matrix is further decomposed and reconstructed, and the different components and different components of the attributes are rearranged according to their contribution degrees. Finally, the dominant earthquake is determined. The dominant component of the attribute provides a data basis for subsequent waveform classification and direct prediction of reservoir parameters. The specific algorithm of singular spectrum analysis is as follows:
嵌入,将优选的属性数据表示为一维数据:[x 1,x 2,…,x N] Embedding, representing preferred attribute data as one-dimensional data: [x 1 , x 2 , ..., x N ]
[x 1,x 2,…,x N] [x 1 , x 2 , ..., x N ]
其中,N为序列长度。where N is the sequence length.
首先选择合适的窗口长度L,将原始时间序列进行滞后排列得到轨迹矩阵:First select an appropriate window length L, and arrange the original time series lag to obtain the trajectory matrix:
Figure PCTCN2021103487-appb-000006
Figure PCTCN2021103487-appb-000006
通常情况下取L<N/2,令K=N-L+1,则轨迹矩阵X为L×K的矩阵:Usually, L<N/2 is taken, and K=N-L+1, then the trajectory matrix X is an L×K matrix:
Figure PCTCN2021103487-appb-000007
Figure PCTCN2021103487-appb-000007
②分解,计算轨迹矩阵的协方差矩阵:② Decompose and calculate the covariance matrix of the trajectory matrix:
S=X·X T   (3) S=X·X T (3)
接下来,对S进行特征值分解得到λ 1>λ 2>…>λ L≥0和对应的特征向量U 1,U 2,…,U L。此时,U=[U 1,U 2,…,U L],
Figure PCTCN2021103487-appb-000008
为原序列的奇异谱,并且有:
Next, perform eigenvalue decomposition on S to obtain λ 12 >...>λ L ≥0 and corresponding eigenvectors U 1 , U 2 ,..., U L . At this time, U=[U 1 , U 2 , . . . , U L ],
Figure PCTCN2021103487-appb-000008
is the singular spectrum of the original sequence, and has:
Figure PCTCN2021103487-appb-000009
Figure PCTCN2021103487-appb-000009
其中:λ m对应的特征向量U m反映了时间序列的演变型。 Among them: The eigenvector U m corresponding to λ m reflects the evolution of the time series.
③分组,假定所有的L个成分分为c个不相交的组,具体公式如下:③ Grouping, assuming that all L components are divided into c disjoint groups, the specific formula is as follows:
Figure PCTCN2021103487-appb-000010
Figure PCTCN2021103487-appb-000010
④重构,首先计算迟滞序列X i在U m上的投影: ④ Reconstruction, first calculate the projection of the hysteresis sequence X i on U m :
Figure PCTCN2021103487-appb-000011
Figure PCTCN2021103487-appb-000011
其中,X i表示轨迹矩阵X的第i列,
Figure PCTCN2021103487-appb-000012
表示X i所反映的时间演变型在原序列的X i+1,x i+2,…,x i+L时段的权重。
where X i represents the i-th column of the trajectory matrix X,
Figure PCTCN2021103487-appb-000012
Indicates the weight of the time evolution type reflected by Xi in the period of Xi +1 , xi +2 , ..., xi+L of the original sequence.
接下来,通过时间经验正交函数和时间主成分来重构信号,具体重构过程如下:Next, the signal is reconstructed through the time empirical orthogonal function and the time principal component. The specific reconstruction process is as follows:
Figure PCTCN2021103487-appb-000013
Figure PCTCN2021103487-appb-000013
这样,重构序列的等于原序列,即:In this way, the reconstructed sequence is equal to the original sequence, namely:
Figure PCTCN2021103487-appb-000014
Figure PCTCN2021103487-appb-000014
其中,
Figure PCTCN2021103487-appb-000015
为按主要性排序的第k个信号。
in,
Figure PCTCN2021103487-appb-000015
is the k-th signal sorted by importance.
因此,通过交汇分析和奇异谱分析,获得优势属性及优势属性的主要分量,为后续储层预测提供数据基础。Therefore, through the intersection analysis and singular spectrum analysis, the dominant attributes and the main components of the dominant attributes are obtained, which provides a data basis for subsequent reservoir prediction.
(2)在多属性优选的基础上,通过SOM无监督聚类算法(图2),来实现波形特征的自动划分,优选地震多属性为输入数据,设计SOM无监督网络训练模型及拓扑结构,输出波形分类结果,为后续储层参数预测提供约束数据。SOM具体算法如下:(2) On the basis of multi-attribute optimization, the SOM unsupervised clustering algorithm (Fig. 2) is used to realize the automatic division of waveform features, and the earthquake multi-attribute is selected as the input data, and the SOM unsupervised network training model and topology are designed. Output waveform classification results to provide constraint data for subsequent reservoir parameter prediction. The specific algorithm of SOM is as follows:
①初始化:每个节点随机初始化自己的参数。每个节点的参数个数与输入数据的维度相同。①Initialization: Each node randomly initializes its own parameters. The number of parameters for each node is the same as the dimension of the input data.
②对于每一个输入数据,找到与它最相配的节点。假设输入是D 维的数据,即X={x_i,i=1,,D},那么判别函数可以为欧几里得距离:②For each input data, find the node that best matches it. Assuming that the input is D-dimensional data, that is, X={x_i, i=1,, D}, then the discriminant function can be Euclidean distance:
Figure PCTCN2021103487-appb-000016
Figure PCTCN2021103487-appb-000016
③找到激活节点I(x)之后,我们也希望更新和它临近的节点。令S_ij表示节点i和j之间的距离,对于I(x)临近的节点,分配给它们一个更新权重:③ After finding the active node I(x), we also want to update the nodes adjacent to it. Let S_ij denote the distance between nodes i and j, and assign an update weight to nodes that are adjacent to I(x):
Figure PCTCN2021103487-appb-000017
Figure PCTCN2021103487-appb-000017
④接着就是更新节点的参数了。按照梯度下降法更新:④ The next step is to update the parameters of the node. Update by gradient descent:
Δw ji=η(t)*T j,I(x)(t)*(x i-w ji)   (12) Δw ji =η(t)*T j, I(x) (t)*( xi -w ji ) (12)
迭代,直至收敛。Iterate until convergence.
因此,通过SOM无监督自动聚类技术,结合基于交汇分析和SSA奇异谱分析的多属性优选技术,实现波形特征自动划分。Therefore, through the unsupervised automatic clustering technology of SOM, combined with the multi-attribute optimization technology based on intersection analysis and SSA singular spectrum analysis, the automatic division of waveform features is realized.
(3)在波形分类的基础上,进一步开展分波形特征的不同深度神经网络构建。由于地震数据具有时序信号特征,且测井数据在纵向上也具有一定关联性,优选LSTM-RNN(长短时记忆-循环神经网络)进行不同地质特征下的非线性多网络预测模型构建(图3)。(3) On the basis of waveform classification, the construction of different deep neural networks with waveform features is further carried out. Since the seismic data has the characteristics of time series signals, and the logging data also has a certain correlation in the vertical direction, the LSTM-RNN (Long Short-Term Memory-Recurrent Neural Network) is preferred to construct a nonlinear multi-network prediction model under different geological characteristics (Fig. 3). ).
LSTM-RNN循环神经网络模型的示意图为图3,一个LSTM单元是由3个门限结构和1个状态向量传输线组成的,门限分别是遗忘门,传入门,输出门;其中状态向量传输线负责长程记忆,只做一些简单的线性操作;3个门负责短时记忆的选择,通过门限设置对输入向量做删除或者添加操作。The schematic diagram of the LSTM-RNN recurrent neural network model is shown in Figure 3. An LSTM unit is composed of three threshold structures and one state vector transmission line. The thresholds are the forget gate, the incoming gate, and the output gate. The state vector transmission line is responsible for long-term memory. , only do some simple linear operations; 3 gates are responsible for the selection of short-term memory, and delete or add operations to the input vector through the threshold setting.
遗忘门(图4)通过一个sigmoid神经层实现,它的作用是决定让哪些信息通过这个单元。0表示“不让任何信息通过”,1表示“让所有信息通过”。The forget gate (Figure 4) is implemented by a sigmoid neural layer, whose role is to decide what information to let through the unit. 0 means "let no information through", 1 means "let all information through".
传入门(图5)的作用是决定让多少新信息加入到单元状态中,传入门实现需要两个步骤:首先,一个sigmod层决定哪些信息需要更新;一个tanh层生成一个备选的用来更新内容;再下一步,将这两部门通 过向量点乘联合起来,对单元的状态进行一个更新。The role of the incoming gate (Figure 5) is to decide how much new information to add to the cell state. The implementation of the incoming gate requires two steps: first, a sigmod layer decides which information needs to be updated; a tanh layer generates an alternative to update content; in the next step, the two departments are combined by vector dot product to update the state of the unit.
输出门(图6)的作用是输出最后的结果,输出门实现需要两个步骤:首先,通过一个sigmoid层决定哪部分信息会被输出;接着,把状态向量通过一个tanh层,然后将tanh层的输出和sigmoid层计算出来的权重相乘,这样就得到了最后输出的结果。The function of the output gate (Figure 6) is to output the final result. The implementation of the output gate requires two steps: first, a sigmoid layer is used to determine which part of the information will be output; then, the state vector is passed through a tanh layer, and then the tanh layer is passed. The output of the sigmoid layer is multiplied by the weight calculated by the sigmoid layer, so that the final output result is obtained.
LSTM单元的具体数学过程如下:The specific mathematical process of the LSTM unit is as follows:
Figure PCTCN2021103487-appb-000018
Figure PCTCN2021103487-appb-000018
其中:i为输入门,σ为逻辑sigmoid函数,W xi、W hi、W ci分别表示输入特征向量、隐藏层单元、单元激活向量与输入门之间的权重矩阵,b i为输入门的偏置量;f为遗忘门,W xf、W hf、W cf分别表示输入特征向量、隐藏层单元、单元激活向量与遗忘门之间的权重矩阵,b f为遗忘门的偏置量;C为单元激活向量,W xc、W hc分别为输入特征向量、隐藏层单元与单元激活向量之间的权重矩阵,所述权重矩阵为对角阵,b c为输出门的偏置值;o为输出门,W xo、W ho、W co分别表示输入特征向量、隐藏层单元、单元激活向量与输出门之间的权重矩阵,b f为遗忘门的偏置量;t作为下标时表示采样时刻,tanh为激活函数。 Among them: i is the input gate, σ is the logical sigmoid function, W xi , W hi , and W ci represent the weight matrix between the input feature vector, the hidden layer unit, the unit activation vector and the input gate, respectively, and b i is the bias of the input gate. set value; f is the forget gate, W xf , W hf , W cf represent the weight matrix between the input feature vector, the hidden layer unit, the unit activation vector and the forget gate, respectively, b f is the bias of the forget gate; C is the Unit activation vector, W xc , W hc are the input feature vector, the weight matrix between the hidden layer unit and the unit activation vector, respectively, the weight matrix is a diagonal matrix, b c is the output gate offset value; o is the output Gate, W xo , W ho , W co represent the weight matrix between the input feature vector, hidden layer unit, unit activation vector and the output gate, respectively, b f is the bias of the forget gate; t as a subscript represents the sampling time , tanh is the activation function.
(4)训练基于LSTM-RNN的深度神经网络模型,并优化调整网络模型参数,使模型泛化、收敛。其输入层为井旁多属性数据,输出层为相应的测井弹性参数,如纵波速度,隐藏层则由:LSTM单元、full-connected层、dropout层、regression层组成,其中:LSTM单元用于保留测井数据和地震数据的时序特征;full-connected层作为整个训练网络的分类器;dropout层用于缓解网络训练过程中过拟合现象的发生,起到正则化的效果;regression层作为网络训练模型的输出。(4) Train the deep neural network model based on LSTM-RNN, and optimize and adjust the parameters of the network model to generalize and converge the model. The input layer is the multi-attribute data next to the well, the output layer is the corresponding logging elastic parameters, such as the longitudinal wave velocity, and the hidden layer is composed of: LSTM unit, full-connected layer, dropout layer, and regression layer, among which: LSTM unit is used for The time series features of logging data and seismic data are preserved; the full-connected layer is used as a classifier for the entire training network; the dropout layer is used to alleviate the occurrence of overfitting during network training and has a regularization effect; the regression layer is used as the network The output of the trained model.
(5)构建空间变化神经网络预测模型集合。在构建空间变化神经网络预测模型集合的基础上,利用波形相似性和空间距离构建每个神经网络模型的空间变化系数(图7),实现空间变化神经网络预测模型集合的构建。空间变化系数的构建公式为:(5) Construct a set of spatially varying neural network prediction models. On the basis of constructing a set of spatially varying neural network prediction models, the spatial variation coefficients of each neural network model are constructed using waveform similarity and spatial distance (Fig. 7) to realize the construction of a set of spatially varying neural network prediction models. The formula for the construction of the spatial variation coefficient is:
w=λw c+(1-λ)w d    (14) w=λw c +(1-λ)w d (14)
Figure PCTCN2021103487-appb-000019
Figure PCTCN2021103487-appb-000019
Figure PCTCN2021103487-appb-000020
Figure PCTCN2021103487-appb-000020
w c=exp(-α cc 12 2)     (17) w c =exp(-α c c 12 2 ) (17)
w d=exp(-α dd 12 2)    (18) w d =exp(-α d d 12 2 ) (18)
式中:w为空间变化系数,v 1为已构建神经网络模型的地震道,v 2为待构建神经网络模型的地震道,w c表示已构建神经网络模型地震道与待构建神经网络模型地震道波形相似性的插值系数,w d表示已构建神经网络模型地震道与待构建神经网络模型地震道距离的插值系数,c 12表示v 1和v 2之间的相关性,d 12表示表示v 1和v 2之间的距离,
Figure PCTCN2021103487-appb-000021
Figure PCTCN2021103487-appb-000022
分别表示v 1和v 2的空间位置,λ为调节因子,α c和α d为指数因子。
In the formula: w is the spatial variation coefficient, v 1 is the seismic trace of the neural network model that has been constructed, v 2 is the seismic trace of the neural network model to be constructed, and w c represents the seismic trace of the neural network model that has been constructed and the seismic trace of the neural network model to be constructed. The interpolation coefficient of the similarity of the trace waveform, w d represents the interpolation coefficient of the distance between the seismic trace of the neural network model that has been constructed and the seismic trace of the neural network model to be constructed, c 12 represents the correlation between v 1 and v 2 , and d 12 represents v the distance between 1 and v2 ,
Figure PCTCN2021103487-appb-000021
and
Figure PCTCN2021103487-appb-000022
represent the spatial positions of v 1 and v 2 , respectively, λ is the adjustment factor, and α c and α d are the exponential factors.
最终,实现空变神经网络预测模型的构建。Finally, the construction of the prediction model of the air-variable neural network is realized.
(6)空间弹性参数预测。以多属性为输入数据,以弹性参数为输出数据,以波形分类结果为约束,通过空间变化神经网络预测模型集合实现空间弹性参数的预测。(6) Prediction of spatial elasticity parameters. Taking multi-attributes as input data, elastic parameters as output data, and waveform classification results as constraints, the prediction of spatial elastic parameters is realized through a set of spatially varying neural network prediction models.
Figure PCTCN2021103487-appb-000023
Figure PCTCN2021103487-appb-000023
其中:V p代表储层参数,f k(x 1,x 2,…x N)代表第k种地质特征所对应的神经网络预测模型,w k,i,j代表第k种地质特征所对应的神经网络预测模型的空间变化 系数,x 1,x 2,…x N代表不同类型的地震属性。 Among them: V p represents the reservoir parameters, f k (x 1 , x 2 ,...x N ) represents the neural network prediction model corresponding to the kth geological feature, wk , i, j represent the kth geological feature corresponding The spatial variation coefficients of the neural network prediction model, x 1 , x 2 , … x N represent different types of seismic attributes.
实施例二 Embodiment 2
下面通过某工区的实际数据来说明本公开方法的有效性。该区为碎屑岩储层类型,共发育两套储层,分别为O72和O73层,O72层为浊积水道席状砂岩,全区发育稳定,该区有效测井共有3口,分别为PU_IA井、PU_IB井、PU_IC井。首先基于交汇分析和奇异谱分析技术优选多属性(图8),优选输入属性分别为:包络属性、相对波阻抗、瞬时振幅属性,并结合SOM无监督聚类算法,进行波形分类(图9),将波形共分为三类,为:能量较弱、能量中等、能量较强,分别对应的三口井为PU_IC井、PU_IB井、PU_IA井。在波形分类的基础上,分波形特征训练深度神经网络,优选输入数据(图10)包括:地震道、包络属性、薄层因子、相对波阻抗、希尔伯特属性、瞬时频率、主频及瞬时相位属性,输出数据为:纵波速度,设计5层深度神经网络(图11),进行预测模型构建,将波形分类结果作为约束数据,最终实现基于深度循环神经网络的多模型弹性参数预测。The effectiveness of the disclosed method is illustrated below through actual data in a certain work area. This area is a clastic rock reservoir type, and two sets of reservoirs are developed, namely O72 and O73 layers, O72 layer is turbidite channel sheet sandstone, the development of the whole area is stable, there are 3 effective logging wells in this area, respectively For PU_IA well, PU_IB well, PU_IC well. Firstly, multiple attributes are optimized based on intersection analysis and singular spectrum analysis technology (Fig. 8). The preferred input attributes are: envelope attribute, relative wave impedance, and instantaneous amplitude attribute. Combined with SOM unsupervised clustering algorithm, waveform classification is performed (Fig. 9). ), the waveforms are divided into three categories: weak energy, medium energy, and strong energy. The three corresponding wells are PU_IC well, PU_IB well, and PU_IA well. On the basis of waveform classification, the deep neural network is trained by waveform features, and the preferred input data (Fig. 10) include: seismic trace, envelope property, thin layer factor, relative wave impedance, Hilbert property, instantaneous frequency, dominant frequency and the instantaneous phase attribute, the output data is: longitudinal wave velocity, a 5-layer deep neural network is designed (Fig. 11), the prediction model is constructed, the waveform classification result is used as the constraint data, and the multi-model elastic parameter prediction based on the deep recurrent neural network is finally realized.
对比基于深度神经网络的多模型弹性参数预测结果与基于深度神经网络的单模型弹性参数预测结果、时间域反演结果以及工程开发部署方案(图12),从平面趋势上可看出,本公开专利与基于单模型预测的纵波速度相比较,具有较好的空间预测精度,且较好地保留了整体宏观特征;本公开专利与时间域反演结果对比可看出,由于时间域反演结果受井及初始模型的限制,反演结果不能较好地表征宏观地质特征,综合图12-a、b、c、d分析,基于多模型的弹性参数直接预测技术具有较好的空间预测精度,且与开发部署方案具有较好的一致性。Comparing the multi-model elastic parameter prediction results based on the deep neural network and the single-model elastic parameter prediction results based on the deep neural network, the time domain inversion results, and the engineering development deployment plan (Fig. 12), it can be seen from the plane trend that the present disclosure Compared with the P-wave velocity predicted based on a single model, the patent has better spatial prediction accuracy, and better retains the overall macroscopic characteristics; it can be seen from the comparison between the disclosed patent and the time domain inversion results, due to the time domain inversion results. Restricted by the well and the initial model, the inversion results cannot well represent the macroscopic geological features. Based on the analysis of Fig. 12-a, b, c, and d, the direct prediction technology of elastic parameters based on multiple models has better spatial prediction accuracy. And it has a good consistency with the development and deployment scheme.
对比PU_IA、PU_IB、PU_IC三口井的基于多模型预测结果与原始测井曲线(图13-a、b、c),可见,纵波速度预测结果与原始测井曲线整体趋势一致,且与井吻合度均较高;进一步,对比PU_IC井的多模型预测结果与单模型预测结果,可见,基于多模型预测的纵波速度预测精度高于基于单模型预测的纵波速度。Comparing the multi-model-based prediction results of the three wells PU_IA, PU_IB, and PU_IC with the original logging curves (Fig. 13-a, b, c), it can be seen that the P-wave velocity prediction results are consistent with the overall trend of the original logging curves, and are in good agreement with the wells Furthermore, comparing the multi-model prediction results and the single-model prediction results of the PU_IC well, it can be seen that the prediction accuracy of the P-wave velocity based on the multi-model prediction is higher than that based on the single-model prediction.
综上所述,基于本公开专利研发了基于LSTM-RNN循环神经网络的储层参数直接预测技术,实现了基于空间变化神经网络预测模型集合的储层参数直接预测,有效保持了地质地层结构,进一步提高了储层参数预测精度。To sum up, based on the disclosed patent, the direct prediction technology of reservoir parameters based on LSTM-RNN cyclic neural network is developed, which realizes the direct prediction of reservoir parameters based on the set of spatially varying neural network prediction models, and effectively maintains the geological stratigraphic structure. The prediction accuracy of reservoir parameters is further improved.
实施例三Embodiment 3
在上一实施例的基础上,本实施例提供一种储层参数预测装置,其特征在于,包括:On the basis of the previous embodiment, the present embodiment provides a reservoir parameter prediction device, which is characterized by comprising:
属性筛选模块,用于利用目标层段的地震数据和测井数据,分析目标层段的不同类型的地震属性与储层参数之间的相关度,根据所述相关度的大小从不同类型的地震属性中选出优势地震属性;The attribute screening module is used to use the seismic data and logging data of the target interval to analyze the correlation between different types of seismic attributes of the target interval and the reservoir parameters. Select the dominant seismic attribute from the attributes;
波形分类模块,用于基于优势地震属性,利用预设的波形分类网络模型将目标层段的地震波形按照波形特征进行分类,获得波形分类结果;其中,不同类型的波形对应表征不同的地质特征;The waveform classification module is used to classify the seismic waveforms of the target interval according to the waveform characteristics by using the preset waveform classification network model based on the dominant seismic attributes, and obtain the waveform classification results; wherein, different types of waveforms correspond to different geological features;
模型构建模块,用于以地震属性为输入,以储层参数为输出,以波形分类结果为约束,构建不同的地质特征所对应的不同的深度神经网络模型;The model building module is used to construct different deep neural network models corresponding to different geological features with seismic attributes as input, reservoir parameters as output, and waveform classification results as constraints;
模型训练模块,用于利用目标层段的地震数据和测井数据作为训练数据和预测数据,对所述不同的深度神经网络模型进行训练,以优化每个深度神经网络模型的模型参数;A model training module for using the seismic data and logging data of the target interval as training data and prediction data to train the different deep neural network models to optimize the model parameters of each deep neural network model;
模型融合模块,用于将训练好的所述不同的深度神经网络模型融合成空间变化神经网络预测模型集合;a model fusion module, used to fuse the trained different deep neural network models into a set of spatially varying neural network prediction models;
参数预测模块,用于利用空间变化神经网络预测模型集合对目标层段的储层参数进行预测。The parameter prediction module is used to predict the reservoir parameters of the target interval by using a set of spatially varying neural network prediction models.
实施例四Embodiment 4
此外,本实施例提供一种计算机存储介质,所述计算机存储介质存储有计算机程序。In addition, this embodiment provides a computer storage medium storing a computer program.
所述计算机存储介质被一个或多个计算机处理器执行时,实现如前所述的储层参数预测方法。The computer storage medium, when executed by one or more computer processors, implements the aforementioned method for predicting reservoir parameters.
上述存储介质可以是闪存、硬盘、多媒体卡、卡型存储器(例如,SD或DX存储器等)、随机访问存储器(RAM)、静态随机访问存储器(SRAM)、只读存储器(ROM)、电可擦除可编程只读存储器(EEPROM)、可编程只读存储器(PROM)、磁性存储器、磁盘、光盘、服务器、App(Application,应用)应用 商城等等。The above-mentioned storage medium can be flash memory, hard disk, multimedia card, card-type memory (for example, SD or DX memory, etc.), random access memory (RAM), static random access memory (SRAM), read only memory (ROM), electrically erasable memory In addition to programmable read-only memory (EEPROM), programmable read-only memory (PROM), magnetic memory, magnetic disk, optical disk, server, App (Application, application) application mall and so on.
实施例五Embodiment 5
另外,本实施例提供一种计算机设备,所述计算机设备包括存储器和处理器。In addition, this embodiment provides a computer device including a memory and a processor.
所述存储器上存储有计算机程序,所述计算机程序被所述处理器执行时,执行如前所述的储层参数预测方法。A computer program is stored in the memory, and when the computer program is executed by the processor, the aforementioned method for predicting reservoir parameters is executed.
处理器可以是专用集成电路(Application Specific Integrated Circuit,简称ASIC)、数字信号处理器(Digital Signal Processor,简称DSP)、数字信号处理设备(Digital Signal Processing Device,简称DSPD)、可编程逻辑器件(Programmable Logic Device,简称PLD)、现场可编程门阵列(Field Programmable Gate Array,简称FPGA)、控制器、微控制器、微处理器或其他电子元件实现,处理器可以用于执行上述实施例一至实施例五中任意一项所述的储层参数预测方法。The processor may be an Application Specific Integrated Circuit (ASIC), a Digital Signal Processor (DSP), a Digital Signal Processing Device (DSPD), or a Programmable Logic Device (Programmable Logic Device). Logic Device (PLD for short), Field Programmable Gate Array (FPGA for short), controller, microcontroller, microprocessor or other electronic components. The reservoir parameter prediction method described in any one of 5.
存储器可以由任何类型的易失性或非易失性存储设备或者它们的组合实现,例如静态随机存取存储器(Static Random Access Memory,简称SRAM),电可擦除可编程只读存储器(Electrically Erasable Programmable Read-Only Memory,简称EEPROM),可擦除可编程只读存储器(Erasable Programmable Read-Only Memory,简称EPROM),可编程只读存储器(Programmable Read-Only Memory,简称PROM),只读存储器(Read-Only Memory,简称ROM),磁存储器,快闪存储器,磁盘或光盘。The memory can be implemented by any type of volatile or non-volatile storage device or their combination, such as Static Random Access Memory (SRAM), Electrically Erasable Programmable Read-Only Memory (Electrically Erasable) Programmable Read-Only Memory (EEPROM for short), Erasable Programmable Read-Only Memory (EPROM), Programmable Read-Only Memory (PROM), Read-Only Memory ( Read-Only Memory, referred to as ROM), magnetic memory, flash memory, magnetic disk or optical disk.
应该理解到,在上述实施例中所描述的装置和方法实施例仅仅是示意性的,例如,附图中的流程图和框图显示了根据本公开的多个实施例的装置、方法和计算机程序产品的可能实现的体系架构、功能和操作。在这点上,流程图或框图中的每个方框可以代表一个模块、程序段或代码的一部分,所述模块、程序段或代码的一部分包含一个或多个用于实现规定的逻辑功能的可执行指令。也应当注意,在有些作为替换的实现方式中,方框中所标注的功能也可以以不同于附图中所标注的顺序发生。例如,两个连续的方框实际上可以基本并行地执行,它们有时也可以按相反的顺序执行,这依所涉及的功能而定。也要注意的是,框图和/或流程图中的每个方框、以及框图和/或流程图中的方框的组合,或者,也可以用 执行规定的功能或动作的专用的基于硬件的系统来实现,或者,还可以用专用硬件与计算机指令的组合来实现。It should be understood that the apparatus and method embodiments described in the above-mentioned embodiments are only illustrative, for example, the flowcharts and block diagrams in the accompanying drawings show apparatuses, methods and computer programs according to various embodiments of the present disclosure The architecture, functionality, and operation of a possible implementation of the product. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of code that contains one or more functions for implementing the specified logical function(s) executable instructions. It should also be noted that, in some alternative implementations, the functions noted in the block may occur out of the order noted in the figures. For example, two blocks in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. It is also noted that each block of the block diagrams and/or flowchart illustrations, and combinations of blocks in the block diagrams and/or flowchart illustrations, alternatively, may be system, or, alternatively, can also be implemented using a combination of dedicated hardware and computer instructions.
另外,在本公开各个实施例中的各功能模块可以集成在一起形成一个独立的部分,也可以是各个模块单独存在,也可以两个或两个以上模块集成形成一个独立的部分。In addition, each functional module in each embodiment of the present disclosure may be integrated together to form an independent part, or each module may exist alone, or two or more modules may be integrated to form an independent part.
所述功能如果以软件功能模块的形式实现并作为独立的产品销售或使用时,可以存储在一个计算机可读取存储介质中。基于这样的理解,本公开的技术方案本质上或者说对现有技术做出贡献的部分或者该技术方案的部分可以以软件产品的形式体现出来,该计算机软件产品存储在一个存储介质中,包括若干指令用以使得一台计算机设备(可以是个人计算机,服务器,或者网络设备等)执行本公开各个实施例所述方法的全部或部分步骤。If the functions are implemented in the form of software function modules and sold or used as independent products, they can be stored in a computer-readable storage medium. Based on this understanding, the technical solutions of the present disclosure can be embodied in the form of software products in essence, or the parts that make contributions to the prior art or the parts of the technical solutions. The computer software products are stored in a storage medium, including Several instructions are used to cause a computer device (which may be a personal computer, a server, or a network device, etc.) to execute all or part of the steps of the methods described in various embodiments of the present disclosure.
还需要说明的是,以上所述仅为本公开的优选实施例而已,并不用于限制本公开,对于本领域的技术人员来说,本公开可以有各种更改和变化。凡在本公开的精神和原则之内,所作的任何修改、等同替换、改进等,均应包含在本公开的保护范围之内。应注意到:相似的标号和字母在下面的附图中表示类似项,因此,一旦某一项在一个附图中被定义,则在随后的附图中不需要对其进行进一步定义和解释。It should also be noted that the above descriptions are only preferred embodiments of the present disclosure, and are not intended to limit the present disclosure. For those skilled in the art, the present disclosure may have various modifications and changes. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present disclosure shall be included within the protection scope of the present disclosure. It should be noted that like numerals and letters refer to like items in the following figures, so once an item is defined in one figure, it does not require further definition and explanation in subsequent figures.

Claims (13)

  1. 一种基于地质特征约束的储层参数预测方法,其特征在于,包括以下步骤:A method for predicting reservoir parameters based on constraints of geological features, comprising the following steps:
    S100、根据目标层段的不同类型的地震属性与储层参数之间的相关度,从不同类型的地震属性中选出优势地震属性;S100, selecting a dominant seismic attribute from different types of seismic attributes according to the correlation between different types of seismic attributes of the target interval and reservoir parameters;
    S200、基于优势地震属性,利用预设的波形分类网络模型将目标层段的地震波形按照波形特征进行分类,获得波形分类结果;其中,不同类型的波形对应表征不同的地质特征;S200 , using a preset waveform classification network model to classify the seismic waveforms of the target interval according to waveform characteristics based on the dominant seismic attributes, to obtain a waveform classification result; wherein, different types of waveforms correspond to different geological features;
    S300、以地震属性为输入,以储层参数为输出,以波形分类结果为约束,构建不同的地质特征所对应的不同的深度神经网络模型;S300 , taking seismic attributes as input, taking reservoir parameters as output, and taking waveform classification results as constraints, constructing different deep neural network models corresponding to different geological features;
    S400、利用目标层段的地震数据和测井数据对所述不同的深度神经网络模型进行训练,以优化每个深度神经网络模型的模型参数;S400, using the seismic data and logging data of the target interval to train the different deep neural network models to optimize the model parameters of each deep neural network model;
    S500、将训练好的不同的深度神经网络模型融合成空间变化神经网络预测模型集合;S500. Integrate different trained deep neural network models into a set of spatially varying neural network prediction models;
    S600、利用空间变化神经网络预测模型集合对目标层段的储层参数进行预测。S600. Use a set of spatially varying neural network prediction models to predict the reservoir parameters of the target interval.
  2. 根据权利要求1所述的储层参数预测方法,其特征在于,所述步骤S100包括以下步骤:The method for predicting reservoir parameters according to claim 1, wherein the step S100 comprises the following steps:
    利用目标层段的地震数据和测井数据,通过交汇分析确定目标层段的不同类型的地震属性与储层参数之间的相关度,根据所述相关度的大小从不同类型的地震属性中选出相关度超过预设相关度阈值的地震属性,作为优势地震属性;Using the seismic data and logging data of the target interval, the correlation between different types of seismic attributes of the target interval and the reservoir parameters is determined through intersection analysis, and the correlation is selected from different types of seismic attributes according to the magnitude of the correlation. The seismic attributes whose correlation exceeds the preset correlation threshold are selected as the dominant seismic attributes;
    对于每一个优势地震属性,通过奇异谱分析对该地震属性的数据进行分解和重构,其中,在重构后的序列中按照对该地震属性的贡献度的大小保留贡献度高于预设贡献度阈值的序列分量,作为该优势地震属性的优势分量。For each dominant seismic attribute, the data of the seismic attribute is decomposed and reconstructed by singular spectrum analysis, wherein in the reconstructed sequence, the contribution degree is kept higher than the preset contribution according to the contribution degree of the seismic attribute The sequence component of the degree threshold is used as the dominant component of the dominant seismic attribute.
  3. 根据权利要求1所述的储层参数预测方法,其特征在于,所述步骤S200中,所述波形分类网络模型为基于SOM无监督聚类算法设计的SOM无监督网络模型,该网络模型包括地震属性输入层和分类结果输出层。The method for predicting reservoir parameters according to claim 1, wherein in the step S200, the waveform classification network model is an SOM unsupervised network model designed based on an SOM unsupervised clustering algorithm, and the network model includes a seismic Attribute input layer and classification result output layer.
  4. 根据权利要求1所述的储层参数预测方法,其特征在于,所述地质特征包括沉积特征。The method for predicting reservoir parameters according to claim 1, wherein the geological features include sedimentary features.
  5. 根据权利要求1所述的储层参数预测方法,其特征在于,所述步骤S300中,每个所述深度神经网络模型为LSTM-RNN循环神经网络模型,该网络模型包括地震属性输入层和储层参数输出层以及位于地震属性输入层与储层参数输出层之间的隐藏层;其中,所述隐藏层包括:The method for predicting reservoir parameters according to claim 1, wherein in the step S300, each of the deep neural network models is an LSTM-RNN recurrent neural network model, and the network model includes a seismic attribute input layer and a reservoir A layer parameter output layer and a hidden layer located between the seismic attribute input layer and the reservoir parameter output layer; wherein the hidden layer includes:
    LSTM单元,用于保留地震数据和测井数据的时序特征;LSTM unit to preserve the time series characteristics of seismic data and logging data;
    full-connected层,用作训练网络模型的分类器full-connected layer, used as a classifier to train the network model
    dropout层,用于缓解网络模型训练过程中的过拟合现象;The dropout layer is used to alleviate the overfitting phenomenon in the network model training process;
    regression层,用作训练网络模型的输出。regression layer, which is used as the output for training the network model.
  6. 根据权利要求1所述的储层参数预测方法,其特征在于,所述步骤S400进一步包括:The method for predicting reservoir parameters according to claim 1, wherein the step S400 further comprises:
    对测井数据进行平滑处理,使得平滑处理后的测井数据的频谱与地震数据的频谱相互匹配;Smoothing the logging data, so that the spectrum of the smoothed logging data matches the spectrum of the seismic data;
    对匹配后的地震数据和测井数据进行归一化处理;Normalize the matched seismic data and logging data;
    以目的层段的顶底为边界,从归一化处理后的地震数据和测井数据中截取属于目的层段范围内的地震数据和测井数据;Taking the top and bottom of the target interval as the boundary, intercept the seismic data and logging data belonging to the target interval from the normalized seismic data and logging data;
    利用属于目的层段范围内的地震数据和测井数据对不同的深度神经网络模型进行训练,以优化每个深度神经网络模型的模型参数。Different deep neural network models are trained using seismic data and logging data belonging to the target interval to optimize the model parameters of each deep neural network model.
  7. 根据权利要求1所述的储层参数预测方法,其特征在于,所述步骤S500中,基于波形的相似性和空间距离确定每个训练好的深度神经网络模型在空间变化神经网络预测模型集合中的空间变化系数。The method for predicting reservoir parameters according to claim 1, wherein in the step S500, it is determined that each trained deep neural network model is included in the set of spatially varying neural network prediction models based on the similarity of the waveforms and the spatial distance. The spatial variation coefficient of .
  8. 根据权利要求1所述的储层参数预测方法,其特征在于,所述步骤S600中,按照下式,将训练好的不同的深度神经网络模型融合成空间变化神经网络预 测模型集合:Reservoir parameter prediction method according to claim 1, is characterized in that, in described step S600, according to the following formula, the different deep neural network models that have been trained are fused into spatial variation neural network prediction model set:
    Figure PCTCN2021103487-appb-100001
    Figure PCTCN2021103487-appb-100001
    其中:V p代表储层参数,f k(x 1,x 2,…x N)代表第k种地质特征所对应的深度神经网络模型,w k,i,j代表第k种地质特征所对应的深度神经网络模型的空间变化系数,x 1,x 2,…x N代表不同类型的地震属性。 Among them: V p represents the reservoir parameters, f k (x 1 , x 2 ,...x N ) represents the deep neural network model corresponding to the kth geological feature, wk , i, j represents the kth geological feature corresponding The spatial variation coefficients of the deep neural network model, x 1 , x 2 , … x N represent different types of seismic attributes.
  9. 根据权利要求5所述的储层参数预测方法,其特征在于,按照下式,确定每个训练好的深度神经网络模型在空间变化神经网络预测模型集合中的空间变化系数:The method for predicting reservoir parameters according to claim 5, wherein, according to the following formula, determine the spatial variation coefficient of each trained deep neural network model in the set of spatially varying neural network prediction models:
    w=λw c+(1-λ)w d w=λw c +(1-λ)w d
    Figure PCTCN2021103487-appb-100002
    Figure PCTCN2021103487-appb-100002
    Figure PCTCN2021103487-appb-100003
    Figure PCTCN2021103487-appb-100003
    w c=exp(-α cc 12 2) w c =exp(-α c c 12 2 )
    w d=exp(-α dd 12 2) w d =exp(-α d d 12 2 )
    式中:w为空间变化系数,v 1为已构建深度神经网络模型的地震道,v 2为待构建深度神经网络模型的地震道,w c表示已构建深度神经网络模型地震道与待构建深度神经网络模型地震道波形相似性的插值系数,w d表示已构建深度神经网络模型地震道与待构建深度神经网络模型地震道距离的插值系数,c 12表示v 1和v 2之间的相关性,d 12表示表示v 1和v 2之间的距离,
    Figure PCTCN2021103487-appb-100004
    Figure PCTCN2021103487-appb-100005
    分别表示v 1和v 2的空间位置,λ为调节因子,α c和α d为指数因子。
    In the formula: w is the spatial variation coefficient, v 1 is the seismic trace of the deep neural network model that has been constructed, v 2 is the seismic trace of the deep neural network model to be constructed, and w c represents the seismic trace of the deep neural network model that has been constructed and the depth to be constructed. The interpolation coefficient of the waveform similarity of the neural network model seismic trace, w d represents the interpolation coefficient of the distance between the seismic trace of the built deep neural network model and the seismic trace of the deep neural network model to be constructed, c 12 represents the correlation between v 1 and v 2 , d 12 represents the distance between v 1 and v 2 ,
    Figure PCTCN2021103487-appb-100004
    and
    Figure PCTCN2021103487-appb-100005
    represent the spatial positions of v 1 and v 2 , respectively, λ is the adjustment factor, and α c and α d are the exponential factors.
  10. 根据权利要求1所述的储层参数预测方法,其特征在于,所述目的层段的储层参数包括目的层段的空间三维弹性参数体,所述方法还包括输出目的层段的空间三维弹性参数体的分布图。The method for predicting reservoir parameters according to claim 1, wherein the reservoir parameters of the target interval include a spatial three-dimensional elastic parameter volume of the target interval, and the method further comprises outputting the spatial three-dimensional elasticity of the target interval Distribution plot of the parametric body.
  11. 一种基于地质特征约束的储层参数预测装置,其特征在于,包括:A device for predicting reservoir parameters based on geological feature constraints, characterized in that it includes:
    属性筛选模块,用于利用目标层段的地震数据和测井数据,分析目标层段的不同类型的地震属性与储层参数之间的相关度,根据所述相关度的大小从不同类型的地震属性中选出优势地震属性;The attribute screening module is used to use the seismic data and logging data of the target interval to analyze the correlation between different types of seismic attributes of the target interval and the reservoir parameters. Select the dominant seismic attribute from the attributes;
    波形分类模块,用于基于优势地震属性,利用预设的波形分类网络模型将目标层段的地震波形按照波形特征进行分类,获得波形分类结果;其中,不同类型的波形对应表征不同的地质特征;The waveform classification module is used to classify the seismic waveforms of the target interval according to the waveform characteristics by using the preset waveform classification network model based on the dominant seismic attributes, and obtain the waveform classification results; wherein, different types of waveforms correspond to different geological features;
    模型构建模块,用于以地震属性为输入,以储层参数为输出,以波形分类结果为约束,构建不同的地质特征所对应的不同的深度神经网络模型;The model building module is used to construct different deep neural network models corresponding to different geological features with seismic attributes as input, reservoir parameters as output, and waveform classification results as constraints;
    模型训练模块,用于利用目标层段的地震数据和测井数据对所述不同的深度神经网络模型进行训练,以优化每个深度神经网络模型的模型参数;a model training module for training the different deep neural network models by using the seismic data and logging data of the target interval to optimize the model parameters of each deep neural network model;
    模型融合模块,用于将训练好的不同的深度神经网络模型融合成空间变化神经网络预测模型集合;The model fusion module is used to fuse different trained deep neural network models into a set of spatially varying neural network prediction models;
    参数预测模块,用于利用空间变化神经网络预测模型集合对目标层段的储层参数进行预测。The parameter prediction module is used to predict the reservoir parameters of the target interval by using a set of spatially varying neural network prediction models.
  12. 一种计算机存储介质,其特征在于,其中存储有可被处理器执行的计算机程序,该计算机程序在被处理器执行时实现上述权利要求1至10中任意一项所述基于地质特征约束的储层参数预测方法。A computer storage medium, characterized in that, a computer program executable by a processor is stored therein, and when the computer program is executed by the processor, the storage medium based on geological feature constraints according to any one of the above claims 1 to 10 is implemented. Layer parameter prediction method.
  13. 一种计算机设备,其特征在于,包括存储器和处理器,所述处理器用于执行所述存储器中存储的计算机程序,所述计算机程序用于实现上述权利要求1至10中任意一项所述基于地质特征约束的储层参数预测方法。A computer device, characterized in that it includes a memory and a processor, and the processor is used to execute a computer program stored in the memory, and the computer program is used to implement the based on any one of the above claims 1 to 10. Reservoir parameter prediction method constrained by geological characteristics.
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